Ice making machine



y 12, 1955 G. M. LEES 2,712,734

ICE MAKING MACHINE Filed Sept. 29, 1952 8 Sheets-Sheet l sew/mama r COMPEL-S501? "mm J i I r INVEVTOR. Z6 66' July 12, 1955 e. M. LEES ICE MAKING MACHINE 8 Sheets-Sheet 2 Filed Sept. 29, 1952 70 COMP/758501? IN VEN TOR.

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ICE MAKING MACHINE Filed Sept. 29, 1952 8 Sheets-Sheet 3 INVEVTOR.

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ICE MAKING MACHINE Filed Sept. 29, 1952 8 Sheets-Sheet 4 INVENTOR. Mleay y 1955 e. M. LEES 2,712,734

ICE MAKING MACHINE Filed Sept. 29, 1952 8 Sheets-Sheet 5 INVENTOR. 16 Gera eea July 12, 1955 e. M. LEES ICE MAKING MACHINE 8 Sheets-Sheet 6 Filed Sept. 29, 1952 INVENTOR. Gez'g/a M Lees y 1955 G. M. LEES 2,712,734

ICE MAKING MACHINE Filed pt. 29, 1952 s Sheets-Sheet '7 July 12, 1955 G. M. LEES ICE MAKING MACHINE 8 Sheets-Sheet 8 Filed Sept. 29, 1952 INVENTOR.

fergz /a M lees atcnt Of 2,?l2,?34 Patented July 12, 1955 ice 2,712,734 ICE R IAKEJG MACHINE Gerald hi. Lees, Seattle, Wash assignor to Col-Flake Corporation, Chicago, 111., a corporation of Iiiinois Application September 29, 1952, Serial No. 311,971 8 Claims. (Cl. 62-107) machines utilizing a heat exchanger having a vertically As is well-known, flake ice is particularly useful in the preservation and cooling of foods and food products and a very high degree of sanitary conditions must be present to prevent the spoilage products with which standards of cleanliness are set by numerous health and 5 food inspection boards and sanitation laws. desirable therefore that any machine for making ice for at all times during operation without costly dismantling for making machine which is itself easily cleaned and mainharvested is clean and uncontaminated.

Another object of my invention is to harvest the ice in such a manner as to separate it from dripping or flowing water, which may, like the ice flakes or chips, be also falling by gravity from the machine.

Another object of my invention is to provide an improved ice forming surface and improved knives or wedging mechanism for removing the ice therefrom.

Another object of my invention is to provide an improved water flow control means for supplying water to the freezing surface in an adjusted quantity, and which means is capable of quick and accurate adjustment, and easily removed for cleaning, repair or replacement.

A further object of my invention is to provide improved means for controlling the water in the circulating system, and means whereby the water supply is automatically replenished whenever the quantity in the supply tank falls below a certain predetermined minimum.

Another object of my invention is to reduce to a minimum relatively moving parts which would require sealing means to prevent leakage.

Another object of my invention is to provide a plurality of improved ice removing knives or wedges, so arranged as to remove all of the ice formed on the freezing surface, and direct it away therefrom to a discharge outlet.

Another object of my invention is to provide means to direct the ice flakes and chips away from the freezing surface to a discharge outlet while permitting excess or dripping water to flow separately into the water reservoirs Without wetting the separated ice flakes and chips.

Another object of my invention is to construct a flake or chip ice making machine which operates with simplicity and ease so as to reduce to a minimum power requirements, repair and maintenance, and to avoid the necessity of employing any specially skilled workmen to operate the machine efliciently.

Additional objects and advantages will be apparent from the following description and accompanying drawings, describing a suitable form of my invention.

In the drawings:

Fig. 1 is a diagrammatic, perspective view of a complete assembly of a suitable machine of my invention;

Fig. 2 is a vertical, sectional view of the machine of Fig. 1, with the housing removed and taken generally along the line 22 of Fig. 1;

Fig. 3 is a plan view of the machine, with the housing removed;

Fig. 4 is a plan sectional view of the heat exchange members and associated parts, taken generally along the line 4-4 of Fig. 2;

Fig. 5 is a similar fragmentary plan sectional view taken generally along the line 55 of Fig. 2;

Fig. 6 is an enlarged fragmentary vertical section of the cutting knives carrier, the heat exchange member, the flow control ring, the water reservoir, and generally associated parts, substantially in the same plane as the right side of the same elements as they appear in Fig. 2;

Fig. 7 is a front perspective view of one of the ice removing knives of my invention, and used in the machine illustrated.

Fig. 8 is a fragmentary plan, sectional view through the heat exchange member, ice removing knife, and knives carrier;

Fig. 9 is a fragmentary vertical sectional view taken on generally similar to Fig. 9 taken on the line 1010 of Fig. 8, as the knives are about to commence cutting and shearing the ice;

Fig. 11 is another view generally similar to Fig. 9, and Fig. 10, taken on the line 11-11 of Fig. 8, showexchange member;

Figs. 12, 13 and 14 are 10, and 11 and illustrate the progressive action as the change member, Fig. 13 illustrating how the space between the blades has decreased further to force the ice from the wall, and Fig. 14 showing the back edges of the knife blades almost as thick as the angle members from which the knives are made engaging the periphery of the heat exchange member wall to separate the chips of ice completely from the wall, so that they 'water through conduits a. may drop by gravity out of the discharge opening at the lower end of the machine;

Fig. is a fragmentary plan sectional view of the discharge spout and associated parts, taken generally on the line15-15 of Fig. 6; and

Fig. 16 is a perspective view of the knives carrier and the discharge spout also carried thereby.

The form of machine utilizing my invention, as shown and described herein, may include a housing 10 for the heat exchange unit 12, an upper housing 14 for the knife carrier drive and associated parts, and a base 16 to which a discharge chute 18 may be attached. A lower water reservoir 26 may be connected to one side of the base 16, the reservoir being connected by a water conduit 22 to a source of water supply. A float valve 24 connected to the conduit 22 is adapted to keep the supply of water at a desired level as shown, the valve being adapted to open whenever the level recedes below a predetermined point. A pump 26 mounted on the top of the reservoir is adapted to pump 28 and 39 to an upper reservoir or water header 32 at the top of the heat exchange unit 12. Other necessary elements may include a compressor 34 for circulating the refrigerating medium through inlet conduit 36 to the lower end of the heat exchange unit 12, an upper conduit 38 which connects to a separator 4d and a gas line 42 returning to the compressor 34- in a manner well known in the art.

The pump 26 may be driven from a motor 44 by means of a belt 46 trained about drive pulley 48 on the motor shaft and pulley 50 on the pump shaft, the belt also passing over an idler pulley 52 and an en larged pulley 54 on the driven shaft 56 of a reducing gear mechanism 58'.

The reducing gear mechanism 58 has a vertical shaft 69 with a drive sprocket 62 keyed thereto, the sprocket driving a' chain 64 trained about an enlarged sprocket 6d keyed to the cutting knives carrier shaft 63.

The shaft 68 may be mounted in suitable bearing members 76 and 72 at the upper and lower ends of the heat exchange unit 12, the upper bearing member 7i) mounted upon a channel-shaped top frame member 74 fastened by bolt members 76 upon a circular angle member 78 secured around the top of cylindrical drum 12a forming part of the heat exchange unit 12. The a; lower bearing member 72 is carried by spider 89 secured in the lower end of the base member 16.

A cover plate round the bearing and protect 82 and cylindrical shell 84-.may surthe same from flake ice dropping from the heat exchange unit, the spider 80' having a plurality of arms efi'extending inwardly from the periphery of the base. A circular angle shaped discharge member 88 may also be mounted in the base 16 above the spider S the same forming in the base a continuation of the lower water reservoir 20.

The heat exchange member 12 may include the cylindrical drum 12a and an inner cdindrical drum 3217, which together with sealing rings 12c adjacent the lower end and 12d adjacent the upper end, form a double-walled heat exchange unit through which the refrigerating medium is circulated so as to freeze a film of ice on the inner surface 122 of the cylindrical member 125 when water is supplied thereto. The conduit for therefrigerating medium thus connects through the outer wall 12a to the cylindrical chamber provided in the heat exchange unit, and the return conduit 38 also connects through the outer wall 12:: at a point adjacent the top of the same. in this'manner and through the use of a compressor and separator, the heat' exchange unit is constantly filled with a refrigerating medium whenever the ice machine is in use.

Referring more specifically to Figs. 4 and 6 of the drawings, it will. be noted that the upper end of the stationary drum or unit 12 is provided with a disc-like a ring-like:

; and 6 that each of the knives ring 91) which has an inner control ring 94 may be mounted directly above this ring, the lower edge 96 of the same being formed with a taper complementary to the bevel 92. The flow control ring 94 is carried by a spider member 98 having a plurality of arms 99 through which bolt members m2 are mounted. The bolt members 1452 are adapted to screw-threadedly engage tapped openings 1G4 in lugs 1 36 extending inwardly from the flow control ring 94.

Thus, when the bolt members are rotated in'a clockwise direction, the flow control ring will be raised, opening the gap between the complementary edges 92 and 96 of the flat disc and the flow control ring 94 respectively. Since the space between the outer drum member 12a of the heat exchange unit 12 and the flow control ring 94 forms an upper water reservoir W at the top of the unit, it can thus be seen that the width of the opening between the beveled edges will control the rate of flow of water down the surface of the inner drum member 12b; and by adjusting the bolt members 162, the rate of flow of water down the surface of the heat exchange unit is accurately and effectively controlled.

By means of cellent water sheet such control, I'have found that an ex- (Reynolds 150-250) in the Reynolds number range may be made, sufficient to meet all requirements for successful freezing, harvesting and separation of ice and water may be obtained with negligible head. it has previously been thought necessary to have a water head of six inches or more, with a correspondingly high initial velocity of five to six feet per second in order to spread and maintain the water in a smooth flat sheet on a refrigerated surface. my novel orifice type of water feeding, perfect sheets are obtained with heads as low as a quarter-inch. For the purpose of cleaning the facing edges or replacing the flow control ring, the spider 93 can be lifted from the top of the heat exchange unit and repaired or re placed with a minimum of effort. 7

The shaft 68 which carries the support for the knives that cut through the ice formed on the inner surface of the wall 121) is provided with a frame or knives carrier which includes upper and lower bracket members 193 and 110, a vertical web 112 joining. the same, and a vertical plate member 114 provided with a plurality of openings 116 to receive bolt members or other fastening means 118 that fasten a vertically aligned row of knife members 120 to the plate 114.

it will be noted by an examination of both Figs. 2 120 is generally formed from an angle member, the particular configuration of which will be explained in further detail hereinafter, each knife member having a pair of tapped openings 122 to receive the bolt members 118 to fasten. the knives firmly in position on the face of theplate 114. It will further be noted that the knives are disposed in aligned juxtaposition so that the cutting edge of each knife is adjacent to the lower edge of each other knife.

The knives carrier also has a. partial cut-off valve sector 124 fastened to the; top of the same by means of bolt members 126, the partial cut-off valve being in the form of a segmental blade 123 which extends in the radius of the internal diameter of the drum 12b as a sector a desired distance on both sides of the knife members 120, for a purpose which will be hereinafter explained.

The lower end of the knives carrier may have 21 segmentally shaped spout 139 secured thereto below the lower bracket portion for the purpose of directing ice chips or flakes downwardly through the opening 88 in the base of the unit. 7

The knives best shown in Figs. 7 to 14 inclusive, are generally angle shaped, as shown, having the back wall 132 and the top wall 134. The wall 134 is machined to provide a sharp leading edge 136 which, when fastened to the plate 114 in operative position, is'projected in a beveled edge 2. A flow With 7 plane at right angles to the ice making surface of the drum 12b, with a trailing edge 138 ground to the approximate radius of the ice making surface of the drum 12b. Thus it will be noted that the leading point 140 of the knife is removed a finite distance from the ice making surface, from which point it slopes toward a point adjacent the surface and from this point the trailing edge 138 conforms to the radius of the surface for the balance of its length.

The action of the knife in scoring and shearing ice I which has formed on the inner wall illustrated ment of the sharp leading edge 136 in cutting or scoring into the wall of ice. In Fig. 11 this showing is slightly more advanced, the leading edge of the knives being shown approximately half way through the wall of ice on the inner surface of the drum 12b.

In Fig. 12, which is the section taken the point of intersection of the tangential portion 138 of that the ice sections which are being out have been compressed slightly, an action which dislodges the ice from the wall.

the trough 130 be directed through the opening 88 in the base of the unit and out of the chute 18.

The excess water, if any,

It will also be noted from the foregoing description that the flow of water in perfect smooth sheets upon the While I have illustrated and described a specific embodiment of the invention, it will be apparent to those is as defined in the following claims.

I claim:

1. In a flake ice making machine, the combination of: a vertical freezing drum having a cylindrical ice-forming surface; means defining an annular Water reservoir located means forming an annular water channel extending from the Water reservoir to the ice forming surface, whereby Water flows from the reservoir to the surface through the channel in a circumferentially continuous thin sheet; and means to remove the ice in flakes as it forms on the freezing surface.

2. In a flake ice making machine, the combination of: a vertical freezing drum having a cylindrical ice-forming surface; means defining an annular water reservoir located means forming an annular water channel extending from the water reservoir to the iceforming surface, whereby Water flows from the reservoir to the surface in a surface as the rotor is turned; and a blade of partially cylindrical conformation complementary to the ice-forming surface seated against said ice-forming surface and mounted for rotation with the rotor to obstruct the water channel in the vicinity of said last means to prevent the flow of water in the vicinity thereof.

3. In a flake ice making machine, the combination of: a vertical freezing drum having a Cylindrical ice-forming part means defining an annular water resersurface in a circumferentially continuous sheet of adjustable rate of flow; and means to remove the ice in flakes as it forms on the freezing surface.

4. In a flake ice making machine, the combination of: a vertical freezing drum having a cylindrical ice-forming surface; a two-part means defining an annular water to the surface in a circumferentially continuous sheet of adjustable rate of flow; a rotor having means to dislodge ice in flakes along a travelling element of said cylindrical ice-forming surface as the rotor is turned; and a wiper blade of partially cylindrical conformation complementary to the ice-forming surface seated against said two-part means to 5. A knife for use in a flake ice making machine having a sur' ace upon which ice is formed in a thin sheet, the knife 6. A flake ice making machine comprising in combination; a freezing member having a face upon which ice is formed; a plurality of vertically aligned knives each having a cutting comparatively thin leading edge and a trailing edge of progressively increased thickness; and means to move the blades across said face in unison to dislodge the ice in flakes therefrom.

7. A flake ice making machine in combination; a freezing member having a face upon which ice is formed; a blade having a two-part edge; and means to move the blade across said surface to dislodge ice in flakes therefrom, one part of the edge of the blade being the leading part and of thin ice scoring conformation and shaped to 7 being comparativelythick to dislodge the ice;

8. in a'flake ice making machine, the combination of: a vertical freezing drum; means defining a water discharge passage at the top of the drum to flow water thereon for freezing, said passage extending entirely about the circumference of the drum to form a circumferentiaily uniform sheet of Water thereon; a rotor having means to dislodge ice in flakes along a travelling element of said cylindrical ice-forming surface as the rotor is turned; and a blade of partially cylindn'cal conformation complementary to the ice-forming surface and mounted for rotation with the rotor to obstruct the water channel in the vicinity of the last means to prevent the flow of water in the vicinity of the same.

L References Cited in theme of this patent UNITED STATES PATENTS Robertshaw Feb. 21, Holden Mar. 19, Taylor Dec. 8, Scheurer Oct. 14, Short Feb. 9, Topping June 12, Walsh Nov. 20, Lessard Feb. 12, Lessard Feb. 12, Lees Nov. 17,

Albright July 13,. 

